Nonadiabatic geometric quantum gates that are insensitive to qubit-frequency drifts

• URL: http://arxiv.org/abs/2103.09005v1
• Date: Tue, 16 Mar 2021 12:05:45 GMT
• Title: Nonadiabatic geometric quantum gates that are insensitive to qubit-frequency drifts
• Authors: Jian Zhou, Sai Li, Guo-Zhu Pan, Gang Zhang, Tao Chen, and Zheng-Yuan Xue
• Abstract summary: In the current implementation of nonadiabatic geometric phases, operational and/or random errors tend to destruct the conditions that induce geometric phases. Here, we apply the path-design strategy to explain in detail why both configurations can realize universal quantum gates in a single-loop way. Our scheme provides a promising way towards practical realization of high-fidelity and robust nonadiabatic geometric quantum gates.
• Score: 8.750801670077806
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Quantum manipulation based on geometric phases provides a promising way towards robust quantum gates. However, in the current implementation of nonadiabatic geometric phases, operational and/or random errors tend to destruct the conditions that induce geometric phases, thereby smearing their noise-resilient feature. In a recent experiment [Y. Xu et al., Phys. Rev. Lett. 124, 230503 (2020)], high-fidelity universal geometric quantum gates have been implemented in a superconducting circuit, which are robust to different types of errors under different configurations of the geometric evolution paths. Here, we apply the path-design strategy to explain in detail why both configurations can realize universal quantum gates in a single-loop way. Meanwhile, we purposefully induce our geometric manipulation by selecting the path configuration that is robust against the qubit-frequency-drift induced error, which is the dominant error source on realistic superconducting circuits and has not been deliberately addressed. Moreover, our proposal can further integrate with the composite scheme to enhance the gate robustness, which is verified by numerical simulations. Therefore, our scheme provides a promising way towards practical realization of high-fidelity and robust nonadiabatic geometric quantum gates.

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